Printer

ABSTRACT

A printer includes a holder configured to house rolled recording paper, a cover that is attached to the holder to be openable and closable relative to the holder, and a contact part that is attached to the cover and configured to contact the recording paper. The contact part is configured such that the contact part substantially point-contacts the recording paper, and positions on the contact part contacting the recording paper change as the recording paper is unrolled.

TECHNICAL FIELD

An aspect of this disclosure relates to a printer.

BACKGROUND ART

There is a known printer that includes a printer body including a paperholder for holding a recording paper roll and a holder cover rotatablysupported by the printer body.

In a method of setting a recording paper roll in the paper holder, thecore of the recording paper roll is attached to a paper-feed shaft ofthe paper holder. Also, drop-in-type printers are becoming popular. Adrop-in-type printer is configured such that a recording paper roll canbe easily placed in a paper holder without passing a paper-feed shaftthrough the recording paper roll.

RELATED-ART DOCUMENTS Patent Document

-   Patent Document 1 Japanese Laid-Open Patent Publication No.    2009-096595

SUMMARY OF INVENTION Technical Problem

In a drop-in-type printer, the recording paper roll moves in the paperholder. Therefore, when the recording paper is pulled out, the recordingpaper roll is pressed against and caught on the holder cover, and therecording paper roll and the holder cover rub together to make a sound(which is hereafter referred to as a “rubbing sound”). Although therubbing sound does not affect the performance of the printer, therubbing sound is not desirable in terms of the quietness of the printer.

One object of this disclosure is to provide a printer with improvedquietness.

Solution to Problem

In an aspect of this disclosure, there is provided a printer including aholder configured to house rolled recording paper, a cover that isattached to the holder to be openable and closable relative to theholder, and a contact part that is attached to the cover and configuredto contact the recording paper. The contact part is configured such thatthe contact part substantially point-contacts the recording paper, andpositions on the contact part contacting the recording paper change asthe recording paper is unrolled.

Advantageous Effects of Invention

An aspect of this disclosure makes it possible to improve the quietnessof a printer.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view of a printer whose cover is open accordingto a first embodiment;

FIG. 2 is a perspective view of a printer whose cover is closedaccording to the first embodiment;

FIG. 3 is a plan view of a cover according to the first embodiment;

FIG. 4 is a cross-sectional view of a printer whose cover is closedaccording to the first embodiment;

FIG. 5 is a cross-sectional view of a printer whose cover is open;

FIG. 6A is a drawing illustrating a printer whose cover is removed;

FIG. 6B is a partial enlarged view of a bearing mechanism of a printeraccording to the first embodiment;

FIG. 7 is an enlarged perspective view of a stopper of a printeraccording to the first embodiment;

FIG. 8 is a drawing illustrating a method of attaching a stopper;

FIG. 9 is a drawing illustrating a method of attaching a stopper;

FIG. 10 is a drawing illustrating a method of attaching a stopper;

FIG. 11 is an enlarged cross-sectional view of a bearing mechanism and adetachment preventing mechanism according to the first embodiment;

FIG. 12 is a drawing illustrating operations of a detachment preventingmechanism according to the first embodiment;

FIG. 13 is a drawing illustrating operations of a detachment preventingmechanism according to the first embodiment;

FIG. 14 is a drawing illustrating operations of a detachment preventingmechanism according to the first embodiment;

FIG. 15 is a plan view of a cover of a printer according to a secondembodiment;

FIG. 16 is a cross-sectional view of a printer whose cover is closedaccording to the second embodiment;

FIG. 17 is a plan view of a cover of a printer according to a thirdembodiment;

FIG. 18 is a cross-sectional view of a printer whose cover is closedaccording to the third embodiment;

FIG. 19 is a plan view of a cover of a printer according to a fourthembodiment;

FIG. 20 is a cross-sectional view of a printer whose cover is closedaccording to the fourth embodiment;

FIG. 21 is a plan view of a cover of a printer according to a fifthembodiment;

FIG. 22 is a cross-sectional view of a printer whose cover is closedaccording to the fifth embodiment;

FIG. 23 is a plan view of a cover of a printer according to a sixthembodiment;

FIG. 24A is a plan view of a cover of a printer according to a seventhembodiment;

FIG. 24B is a side view of a cover of a printer according to the seventhembodiment;

FIG. 25 is a plan view of a cover of a printer according to an eighthembodiment;

FIG. 26 is a plan view of a cover according to a comparative example;and

FIG. 27 is a cross-sectional view of a printer where the cover of thecomparative example is closed.

DESCRIPTION OF EMBODIMENTS

Non-limiting embodiments of the present invention are described belowwith reference to the accompanying drawings.

Throughout the accompanying drawings, the same or correspondingreference numbers are assigned to the same or corresponding components,and repeated descriptions of those components are omitted. Unlessotherwise mentioned, the drawings do not indicate relative sizes ofcomponents.

The embodiments described below are examples, and the present inventionis not limited to those embodiments. Also, not all of the features andtheir combinations described in the embodiments may be essential to thepresent invention.

FIGS. 1 through 6B are drawings illustrating a printer 1A of a firstembodiment.

FIG. 1 is a perspective view of the printer 1A where a cover 20A isopen. FIG. 2 is a perspective view of the printer 1A where the cover 20Ais closed. FIG. 3 is a plan view of the cover 20A. FIG. 4 is across-sectional view of the printer 1A where the cover 20A is closed.FIG. 5 is a cross-sectional view of the printer 1A where the cover 20Ais open. FIG. 6A is a drawing illustrating a state where the cover 20Ais removed from a body 10. FIG. 6B is a partial enlarged view of abearing mechanism. In the descriptions below, the direction ofgravitational force is referred to as a “downward direction”, and adirection opposite of the downward direction is referred to as an“upward direction”.

The printer 1A is a drop-in-type printer, and includes a holder 11 thatcan hold recording paper 100 without using a paper-feed shaft.

The printer 1A includes the body 10, the cover 20A, a bearing 50, acontact part 60A, and a detachment preventing mechanism 70A.

The body 10 houses the recording paper 100, and a part of a printingmechanism is mounted on the body 10. The holder 11, a circuit board 12,motors 13 and 14, a thermal head 40, and a fixed blade 41 are disposedon the body 10.

The holder 11 and the body 10 are formed as a monolithic part. Asillustrated in FIG. 1, the holder 11 has a large opening so that therecording paper 100 can be placed in the holder 11.

The recording paper 100 is thermal paper and placed in the holder 11 ina rolled state. Hereafter, the rolled recording paper 100 is alsoreferred to as a paper roll 100 a.

Multiple ribs 16 are formed on the inner wall of the holder 11. The ribs16 can reduce the contact area between the paper roll 100 a placed inthe holder 11 and the inner wall of the holder 11, and can reduce thefriction between the paper roll 100 a and the inner wall.

As illustrated in FIG. 4, the circuit board 12 is disposed on the upperback side of the body 10, and includes a control circuit for controllingthe printer 1A. One of the motors 13 and 14 is used to feed therecording paper 100, and the other one of the motors 13 and 14 is usedto drive a movable blade 42.

As illustrated in FIG. 6A, shaft holes 17 (only one of the shaft holes17 is illustrated in FIG. 6A) are formed in the right and left innerwalls of the holder 11. The shaft holes 17 constitute a part of thebearing 50, and the cover 20A is rotatably attached to the shaft holes17. In FIG. 6A, only a cover body 23 and the body 10 are illustrated,and other components such as the motors 13 and 14 and a platen roller 45are omitted.

The thermal head 40 is disposed on the upper part of the body 10 andperforms printing on the recording paper 100.

After information is printed, the recording paper 100 is cut by a cutterincluding the fixed blade 41 and the movable blade 42. The fixed blade41 is disposed on the upper part of the body 10 at a position that isdownstream of the location of the thermal head 40.

The cover 20A includes a lever 21, the cover body 23, the movable blade42, and the platen roller 45.

The lever 21 is used to open the cover 20A, and is movable in a groove22 formed in a surface of the cover body 23. When closed, the cover 20Ais locked by a locking mechanism (not shown). Hereafter, the state wherethe cover 20A is closed is referred to as a “closed state”.

The cover 20A can be opened by sliding the lever 21 downward and therebyunlocking the locking mechanism. Hereafter, the state where the cover20A is open is referred to as an “open state”.

The cover body 23 is a base of the cover 20A. The movable blade 42, theplaten roller 45, the contact part 60A, and a stopper 80A are disposedon the cover body 23. The cover body 23 is formed by integral molding ofa resin.

Side plates 24 are formed on the sides of the back surface, i.e., asurface facing the body 10, of the cover body 23. The side plates 24 andthe cover body 23 are formed as a monolithic part. The side plates 24are perpendicular to the back surface of the cover body 23. Shafts 28constituting a part of the bearing 50 are formed on the outer sides ofthe corresponding side plates 24. The shafts 28 protrude outward fromthe outer sides of the side plates 24.

The movable blade 42 is disposed to face the fixed blade 41 on the body10 when the cover 20A is closed. The recording paper 100 fed from theholder 11 is ejected through a gap between the fixed blade 41 and themovable blade 42, and is cut by the fixed blade 41 and the movable blade42 that is moved by a motor toward the fixed blade 41.

The platen roller 45 is disposed on the upper part of the cover 20A. Inthe closed state, information is printed on the recording paper 100 thatis fed from the holder 11 and sandwiched between the thermal head 40 andthe platen roller 45.

In the closed state, a space for housing the recording paper 100 isformed between the inner wall of the cover 20A and the inner wall of theholder 11. Hereafter, the space formed between the cover 20A and theholder 11 is referred to as a housing chamber 15.

When the lever 21 is operated in the closed state, the cover 50supported by the bearing rotates, and the printer 1A changes to the openstate illustrated in FIGS. 1 and 5. In the open state, the housingchamber 15 is open and the paper roll 100 a can be placed in the holder11 as illustrated in FIG. 5. The paper roll 100 a is housed in thehousing chamber 15 by closing the cover 20A.

FIG. 4 illustrates a state where the paper roll 100 a is housed in thehousing chamber 15. In a printing process, the recording paper 100 isfed from the paper roll 100 a in an upward direction in FIG. 4,information is printed on the recording paper 100 by the thermal head40, and the recording paper 100 is ejected from an exit of the printer1A in a direction B (indicated by an arrow B).

Because the printer 1A is a drop-in-type printer, the paper roll 100 ain the housing chamber 15 moves in the lateral direction in FIG. 4. Whenthe recording paper 100 is pulled out from the upper part of the printer1A, the paper roll 100 a rotates in a direction A (indicated by an arrowA) in the housing chamber 15, and moves in a direction C (indicated byan arrow C) toward the cover 20A.

FIG. 26 is a plan view of a cover 220 of a comparative example. FIG. 27is a cross-sectional view of a printer 200 of the comparative examplewhere the cover 220 is closed.

The printer 200 is also a drop-in-type printer. Four ribs 225 are formedon the inner wall of the cover 220. The ribs 225 extend along the innerwall of the cover 220 in the vertical direction in FIG. 26.

When the recording paper 100 is pulled out at high speed, the paper roll100 a moves fast in the housing chamber 15. As a result, the surface ofthe paper roll 100 a is caught on the ribs 225, the paper roll 100 a andthe ribs 225 collide with each other, and the paper roll 100 a and theribs 225 rub together to make a rubbing sound.

The surface of the paper roll 100 a contacts the ribs 225 at lowpositions (which are hereafter referred to as “contact positions”) thatare indicated by hatching in FIG. 26. Accordingly, much of the rubbingsound is generated at the contact positions. The generation of therubbing sound is not desirable in terms of the quietness of the printer200.

Here, the ribs 225 extend in the vertical direction parallel to eachother, and the paper roll 100 a does not move in the lateral directionin the housing chamber 15 even when the diameter of the paper roll 100 adecreases as the recording paper 100 is pulled out. Therefore, the ribs225 are pressed against the same positions on the paper roll 100 a inthe width direction.

Because the ribs 225 are pressed against the same positions on the paperroll 100 a, indentations are formed on the paper roll 100 a.

To prevent this problem, the contact part 60A, which contacts the paperroll 110 a in the housing chamber 15, is provided on the cover 20A ofthe printer 1A of the present embodiment.

Next, the contact part 60A is described.

As illustrated in FIGS. 3 and 4, the contact part 60A is disposed on theinner wall of the cover 20A. The contact part 60A is a single componentformed of a metal wire with a circular cross section, and includes anangled portion 61A, attaching portions 62A, and supporting portions 63A.A spring material may be used for the metal wire.

The contact part 60A is not necessarily formed of a metal, and may bemade of a resin. Also, the cross-section of the contact part 60A is notlimited to a circular shape, and may have any other shape as long as thecontact part 60A can smoothly contact the paper roll 100 a.

As illustrated in FIG. 3, the angled portion 61A has a substantiallyinverted-V shape. In the present embodiment, the contact part 60Aincludes one angled portion 61A. The angled portion 61A includes a peakportion 64A that protrudes upward and is located in the middle of theangled portion 61A in the horizontal direction (the lateral direction inFIG. 3), and inclined portions 61A-1 and 61A-2 that extend diagonallyand are located to the left and right of the peak portion 64A in FIG. 3.The height of the peak portion 64A from the bottom of the housingchamber 15 is greater than the maximum radius of the paper roll 100 aplaced in the housing chamber 15.

The attaching portions 62A are detachably attached to protrusions 26.Each supporting portion 63A is located between the angled portion 61Aand the corresponding attaching portion 62A, and supports the angledportion 61A together with the attaching portion 62A. The supportingportions 63A extend downward from the corresponding ends of the angledportion 61A. The supporting portions 63A are disposed in grooves formedin the side plates 24.

The contact part 60A is attached to the cover 20A by attaching theattaching portions 62A to the protrusions 26, and the contact part 60Ais detached from the cover 20A by detaching the attaching portions 62Afrom the protrusions 26. Configuring the contact part 60A to beattachable and detachable to and from the cover 20A as described abovemakes it easier to maintain the contact part 60A.

The attaching portions 62A may instead be attached to parts of the cover20A other than the protrusions 26. Also, the attaching portions 62A maybe fixed to the cover 20A such that the contact part 60A is notdetachable.

Next, operations of the contact part 60A are described.

As illustrated in FIGS. 4 and 5, when not in contact with the paper roll100 a, the angled portion 61A is inclined forward with respect to theinner wall of the cover 20A.

When the diameter of the paper roll 100 a is large, the paper roll 100 ain the housing chamber 15 contacts the contact part 60A. When thediameter of the paper roll 100 a decreases as the recording paper 100 ispulled out, the paper roll 100 a moves in the direction C toward thecover 20A and contacts the contact part 60A.

When the paper roll 100 a moves or the diameter of the paper roll 100 ais large, the angled portion 61A is pressed by the paper roll 100 a andis elastically deformed in a direction D (indicated by an arrow D)toward the cover 20A.

The paper roll 100 a is biased to the right in FIG. 4 by the elasticityof the angled portion 61A that is elastically-deformed due to themovement of the paper roll 100 a, and the moving force of the paper roll100 a toward the cover 20A is reduced by the biasing force. Thisconfiguration can prevent fast movement of the paper roll 100 a towardthe cover 20A, reduce the rubbing sound that is generated when the paperroll 100 a contacts the angled portion 61A, and improve the quietness ofthe printer 1A.

How the paper roll 100 a and the angled portion 61A contact each otheris described below.

In the descriptions below, the side of the cover 20A where the platenroller 45 is provided is referred to as an upper side, and the side ofthe cover 20A where the shafts 28 are provided is referred to as a lowerside.

The contact part 60A provided on the cover body 23 of the presentembodiment has an inverted-V shape protruding upward and having an apexon the upper side. In the example of FIG. 3, one contact part 60A isprovided on the cover body 23. The height of the peak portion 64A in themiddle of the contact part 60A is greater than the maximum radius of thepaper roll 100 a placed in the housing chamber 15. Regardless of thediameter of the paper roll 100 a in the housing chamber 15, the angledportion 61A contacts the paper roll 100 a at two positions.

The contact part 60A is formed of a metal wire with a circular crosssection, and the angled portion 61A, which contacts the paper roll 100a, includes the inclined portions 61A-1 and 61A-2 that are inclined withrespect to the axial direction of the paper roll 100 a. Therefore, theangled portion 61A and the paper roll 100 a substantially point-contacteach other.

Here, “substantially point-contact” indicates not only a “point contact”in a strict sense but also a contact that is deemed to be a pointcontact. The “contact deemed to be a point contact” includes a pointcontact and a line contact with a contact area smaller than the contactarea between the paper roll 100 a and the ribs 225 in the comparativeexample.

The contact area between the angled portion 61A and the paper roll 100 achanges depending on the pressing force at which the paper roll 100 a ispressed against the contact part 60A. The “contact deemed to be a pointcontact” also includes a contact with a contact area within a variationrange corresponding to the changes in the pressing force.

When the paper roll 100 a is unrolled while in contact with the angledportion 61A, friction occurs between the rotating paper roll 100 a andthe angled portion 61A. In the present embodiment, the paper roll 100 aand the angled portion 61A substantially point-contact each other, andthe contact area between the paper roll 100 a and the angled portion 61Ais smaller than the contact area between the paper roll and the ribs inthe comparative example. Therefore, the friction between the contactpart 60A and the paper roll 100 a is smaller than the friction in thecomparative example, and the paper roll 100 a rotates smoothly.Accordingly, the present embodiment can reduce the rubbing soundgenerated at the contact between the paper roll 100 a and the angledportion 61A, and can provide the printer 1A with improved quietness.

As the recording paper 100 is pulled out and the diameter of the paperroll 100 a decreases, the positions on the paper roll 100 a contactingthe angled portion 61A change in the width direction of the paper roll100 a. Changes in the contact positions between the paper roll 100 a andthe angled portion 61A are described with reference to FIGS. 3 and 4.

In FIG. 4, a paper roll 100 a-1 (which is hereafter referred to as alarge paper roll) indicates the paper roll 100 a whose diameter is atthe maximum. A paper roll 100 a-2 (which is hereafter referred to as amedium paper roll) indicates the paper roll 100 a whose diameter isreduced to about two thirds of the maximum diameter. A paper roll 100a-3 (which is hereafter referred to as a small paper roll) indicates thepaper roll 100 a whose diameter is reduced to about one third of themaximum diameter.

Because the diameter is large, the large paper roll 100 a-1 contacts theangled portion 61A at two upper contact positions P1 in FIG. 3 that areclose to the peak portion 64A. The two contact positions P1 contactingthe large paper roll 100 a-1 are close to each other.

When the recording paper 100 is pulled out and the diameter of the paperroll 100 a decreases, the paper roll 100 a becomes the medium paper roll100 a-2. The medium paper roll 100 a-2 contacts the angled portion 61Aat contact positions P2 that are located lower than and outer than thecontact positions P1 in FIG. 3.

When the diameter of the paper roll 100 a further decreases, the paperroll 100 a becomes the small paper roll 100 a-3. The small paper roll100 a-contacts the angled portion 61A at contact positions P3 that arelocated lower than and outer than the contact positions P2 in FIG. 3.

As described above, because the angled portion 61A has an inverted-Vshape and the diameter of the paper roll 100 a gradually decreases,positions on the paper roll 100 a contacting the angled portion 61Achange as the recording paper 100 is pulled out and gradually move inthe outward direction. Thus, because the positions on the paper roll 100a contacting the angled portion 61A change as the diameter of the paperroll 100 a decreases, even when the paper roll 100 a is pressed againstthe angled portion 61A, formation of indentations on the recording paper100 is prevented.

Next, the detachment preventing mechanism 70A is described withreference to FIGS. 6A through 14.

With the shafts 28 fitted into the shaft holes 17, the cover 20A isrotatably attached to the body 10. However, when an external force isapplied to the cover 20A as a result of, for example, dropping the paperroll 100 a to be placed in the housing chamber 15 onto the cover 20A,the side plates 24 are displaced inward and the shafts 28 may come outof the shaft holes 17. The detachment preventing mechanism 70A of thepresent embodiment prevents the cover 20A from being detached from thebody 10 even when an external force is applied to the cover 20A.

The detachment preventing mechanism 70A includes recesses 29, grooves27, and the stopper 80A.

The recesses 29 are closed-end holes formed in the inner walls of theside plates 24 of the cover body 23. A protruding surface 29 aprotruding inward from the side plate 24 is formed around each recess 29(see FIG. 6B).

In the present embodiment, the recesses 29 are disposed at positionsthat are shifted from the positions where the shafts 28 are formed.However, to prevent the shafts 28 from coming out of the shaft holes 17,the shafts 28 and the recesses 29 are preferably close to each other andmay be disposed on the same axis.

The stopper 80A is attached to the grooves formed in ribs 25.Protrusions 26 are formed on the sides of each groove 27. The groove 27is formed between the protrusions 26, and the height of the bottomsurface of the groove 27 is substantially the same as the height of theinner wall of the cover body 23. The grooves 27 are disposed on a lineconnecting the right and left recesses 29.

The grooves 27 are not necessarily formed in the ribs 25, and may beformed in other positions on the inner surface of the cover body 23.

The stopper 80A includes a stopper body 81A, protrusions 82, and stoppersurfaces 83. The stopper body 81A is shaped like a rod with asemi-cylindrical cross section. Multiple reinforcing ribs 84 are formedin a space inside of the stopper body 81A. The strength of the stopper80A can be adjusted by changing the number and the positions of thereinforcing ribs 84.

The stopper body 81A may also have a cross-sectional shape other thanthe semi-cylindrical shape such as a circular shape, a rectangularshape, or an elliptical shape. Also, the reinforcing ribs 84 may beomitted and may be provided when it is necessary to adjust the strengthof the stopper 80A.

The protrusions 82 and the stopper surfaces 83 are formed at the ends ofthe stopper body 81A. Each protrusion 82 has a cylindrical shape andengages with the corresponding recess 29. Each stopper surface 83 isformed at a position that is shifted from the protrusion 82 toward abottom surface 87.

Next, a method of attaching the stopper 80A to the cover 20A isdescribed.

FIG. 6A illustrates a state where the cover 20A is detached from thebody 10. The cover 20A is attached to the body 10 before the stopper 80Ais attached to the cover 20A. The cover 20A is attached to the body 10by fitting the shafts 28 formed on the side plates 24 into the shaftholes 17. The shafts 28 are fitted into the shaft holes as indicated bya dashed-dotted line that is indicated by an arrow G in FIG. 6A.

FIG. 8 illustrates a state where the cover 20A is attached to the body10. The stopper 80A is attached to the cover 20A after the cover 20A isattached to the body 10. Specifically, as indicated by a dashed-dottedline in FIG. 8, the protrusions of the stopper 80A are inserted into therecesses 29 formed in the side plates 24.

FIG. 9 illustrates a state where the protrusions 82 of the stopper 80Aare inserted in the recesses 29 formed in the side plates 24. When theprotrusions 82 are inserted in the recesses 29, the stopper 80A ispositioned in the grooves 27. In this state, the stopper surfaces 83,which are offset from the protrusions 82, face the protruding surfaces29 a formed around the respective recesses 29.

In FIG. 9, the stopper 80A is attached to the cover 20A with the bottomsurface 87 (see FIG. 7) facing upward. That is, the stopper 80A isattached to the cover 20A in an incorrect orientation. In this case, asindicated by an arrow in FIG. 9, the stopper 80A is rotated so that thebottom surface 87 of the stopper 80A faces the inner wall of the cover20A.

FIG. 10 illustrates a state where the stopper 80A is properly attachedto the cover 20A. When the stopper 80A is properly attached to the cover20A, the curved surface of the stopper 80A faces upward, and the designof the printer is improved. This also makes it possible to prevent thestopper 80A from damaging the paper roll 100 a placed in the housingchamber 15.

Also, when the stopper 80A is properly attached to the cover 20A, thestopper body 81A engages with the protrusions 26, and the bottom surface87 contacts the inner wall of the cover body 23. Thus, the stopper 80Ais positioned by the grooves 27 and the inner wall of the cover body 23.

FIG. 11 illustrates the bearing 50 and the detachment preventingmechanism 70A in a state where the stopper 80A is attached to the cover20A. FIG. 11 is an enlarged cross-sectional view of a part indicated bya dashed-dotted line C in FIG. 10.

In a state where the cover 20A is attached to the body 10 and thestopper 80A is attached to the cover 20A, the shafts 28 are fitted intothe shaft holes 17 and the protrusions 82 of the stopper 80A are fittedinto the recesses 29. Although not illustrated in FIG. 11, the stoppersurfaces 83 face the protruding surfaces 29 a. In the presentembodiment, the central axis (a dashed-dotted line indicated by an arrowH in FIG. 11) of the bearing 50 and the central axis (a dashed-dottedline indicated by an arrow K in FIG. 11) of the detachment preventingmechanism 70A are shifted from each other by a distance ΔH.

Next, the workings of the detachment preventing mechanism 70A when anexternal force is applied to the cover 20A in the open state aredescribed.

FIG. 12 illustrates a state where an external force F1 is applieddownward to the cover 20A in the open state.

When the external force F1 is applied and the cover 20A is presseddownward, the side plates of the cover 20A fall inward relative to theholder 11. That is, when the cover 20A is pressed downward, a force(indicated by an arrow F2 in FIG. 12) that causes the shaft 28 to comeout of the shaft hole 17 is applied between the inner wall of the holder11 and each of the side plates 24. When the force F2 is applied, becausethe side plates 24 are thinner and have lower strength than the innerwall of the holder 11, the side plates 24 are displaced inward.

However, because the stopper 80A is provided between the facing sideplates 24, the side plates 24 displaced inward by the force F2 contactthe stopper surfaces 83 at the ends of the stopper 80A, and the inwardmovement of the side plates 24 is limited. Also, because the recesses 29are biased toward the protrusions 82 by the inward movement of the sideplates 24, the protrusions 82 do not come out of the recesses 29 evenwhen the force F2 is applied to the side plates 24.

Thus, the detachment preventing mechanism 70A can limit the movement ofthe side plates 24 and prevent the shafts 28 from coming out of theshaft holes 17. This in turn makes it possible to prevent the cover 20Afrom being detached from the body 10 even when an external force isapplied to the cover 20A, and improve the reliability of the printer 1A.

Here, there may be a case where a very large external force that thestopper 80A cannot sustain is applied to the cover 20A. With theconfiguration where the stopper 80A supports the side plates 24, whensuch a large external force is applied to the cover 20A, the side plates24 may be damaged, the stopper 80A may be broken, and/or the protrusions82 may be crushed. Thus, providing the stopper 80A may result indamaging the cover 20A.

Accordingly, to prevent damage to the printer 1A, it is preferable torelease the stopper 80A supporting the side plates 24 and allow thecover 20A to be detached from the body 10 when a large external force isapplied to the cover 20A. For this reason, in the present embodiment,the detachment preventing mechanism 70A is configured such that thestopper 80A is detached from the cover 20A when a large external forceis applied to the cover 20A.

The workings of the detachment preventing mechanism 70A when a largeexternal force is applied to the cover 20A are described with referenceto FIGS. 13 and 14.

FIG. 13 illustrates a state where an external force is applied to thecover 20A and a force (which is hereafter referred to as an externalforce F3) indicated by an arrow F3 is applied to the ends of the stopper80A.

When the external force is applied to the cover 20A and the side plates24 fall inward, the side plates 24 contact the stopper surfaces 83 ofthe stopper 80A. As a result, the external force F3 is applied to thestopper surfaces 83.

Because the stopper surfaces 83 are offset from the center of thestopper 80A, the external force F3 applied to the stopper surfaces 83generates a moment on the stopper 80A, and the stopper 80A is deformedinto an arcuate shape as indicated by a dashed-dotted line in FIG. 13.

When the stopper 80A is deformed into an arcuate shape, the protrusions82 move apart from the recesses 29, and the stopper 80A is disengagedfrom the cover 20A. As a result, the stopper 80A becomes detachable fromthe cover 20A. FIG. 14 illustrates a state where the stopper 80A isdetached from the cover 20A.

When the protrusions 82 are disengaged from the recesses 29, the stopper80A deformed into the arcuate shape tends to recover its original shapedue to elasticity. The stopper 80A whose protrusions 82 are disengagedfrom the recesses 29 jumps out of the cover 20A due to this recoveringforce. With the above configuration of the detachment preventingmechanism 70A, the stopper 80A is automatically detached from the cover20A when a large external force is applied. For example, thisconfiguration can prevent the side plates 24 from being damaged, preventthe stopper 80A from being broken, and prevent the protrusions 82 frombeing crushed.

The amount by which the stopper 80A deforms when the external force F3is applied can be adjusted by, for example, changing the number of thereinforcing ribs 84 provided in the stopper body 81A.

Next, printers 1B through 1E according to other embodiments aredescribed.

FIGS. 15 through 22 are drawings illustrating the printers 1B through 1Eaccording to other embodiments. The same reference numbers as thoseassigned to the components of the printer 1A of the first embodiment areassigned to the corresponding components in FIGS. 15 through 22, andrepeated descriptions of those components may be omitted.

FIGS. 15 and 16 illustrate the printer 1B according to a secondembodiment. FIG. 15 is a plan view of the cover 20A, and FIG. 16 is across-sectional view of the printer 1B with the cover 20A closed.

A contact part 60B of the printer 1B also includes one angled portion61B. The angled portion 61B in FIG. 15 includes a peak portion 64B thatprotrudes downward.

The ends of the angled portion 61B are connected to the upper ends ofsupporting portions 63B that extend upward from attaching portions 62B.

As indicated by a dotted line in FIG. 16, when not in contact with thepaper roll ⋅100 a, the angled portion 61B is inclined forward withrespect to the inner wall of the cover 20A. Also in the secondembodiment, when the paper roll 100 a contacts the angled portion 61B,the angled portion 61B is elastically deformed in a direction D(indicated by an arrow D) toward the cover 20A.

The moving force of the paper roll 100 a toward the cover 20A is reducedby the elastic force generated by elastic deformation of the angledportion 61B. This configuration can prevent fast movement of the paperroll 100 a toward the cover 20A, reduce the rubbing sound that isgenerated when the paper roll 100 a contacts the angled portion 61B, andimprove the quietness of the printer 1B.

Also in the second embodiment, the contact part 60B is formed of a wire,and substantially point-contacts the paper roll 100 a. Accordingly, thefriction between the contact part 60B and the paper roll 100 a isreduced, and the rubbing sound generated when the paper roll 100 acontacts the angled portion 61B is reduced.

FIGS. 17 and 18 illustrate the printer 1C according to a thirdembodiment. FIG. 17 is a plan view of the cover 20A, and FIG. 18 is across-sectional view of the printer 1C with the cover 20A closed.

While the contact parts 60A and 60B in FIGS. 3 and 15 are formed ofmetal wires, a contact part 60C of the third embodiment is formed bypressing a metal plate into an inverted-V shape.

The contact part 60C includes an angled portion 61C. The ends of theangled portion 61C are attached via attaching portions 62C to the cover20A. The height of the upper side of a peak portion 64C of the angledportion 61C is greater than the maximum radius of the paper roll 100 aplaced in the housing chamber 15.

As indicated by a dotted line in FIG. 18, when not in contact with thepaper roll 100 a, the angled portion 61C is inclined forward withrespect to the inner wall of the cover 20A. Also in the thirdembodiment, when the paper roll 100 a contacts the angled portion 61C,the angled portion 61C is elastically deformed and the moving force ofthe paper roll 100 a is reduced. This configuration can reduce therubbing sound that is generated when the paper roll 100 a contacts theangled portion 61C, and improve the quietness of the printer 1C.

In the third embodiment, the contact part 60C is configured such thatupper outer edges 65 of the angled portion 61C close to the platenroller 45 contact the paper roll 100 a. The edges 65 extend obliquelydownward and outward from the peak portion 64C.

Because the edges 65 contact the paper roll 100 a, the angled portion61C and the paper roll 100 a substantially point-contact each other.Accordingly, the friction between the contact part 60C and the paperroll 100 a is reduced, and the rubbing sound generated when the paperroll 100 a contacts the contact part 60C is reduced.

Also, because the angled portion 61C has an inverted-V shape, thepositions on the paper roll 100 a contacting the edges 65 change in thewidth direction of the paper roll 100 a as the diameter of the paperroll 100 a decreases. Thus, the printer 1C can also prevent formation ofindentations on the recording paper 100.

FIGS. 19 and 20 illustrate the printer 1D according to a fourthembodiment. FIG. 19 is a plan view of the cover 20A, and FIG. 20 is across-sectional view of the printer 1D with the cover 20A closed.

The printer 1D illustrated by FIGS. 19 and 20 includes a contact part60D that is formed of a sound-absorbing material. In the fourthembodiment, the contact part 60D is formed of a sponge. However, thematerial of the contact part 60D is not limited to a sponge, and thecontact part 60D may be formed of any material that can maintain apredetermined shape and has a sound-absorbing function.

The contact part 60D includes one angled portion 61D. The ends of theangled portion 61D are attached via attaching portions 62D to the cover20A. The height of a peak portion 64D is greater than the maximum radiusof the paper roll 100 a placed in the housing chamber 15.

The contact part 60D has a predetermined thickness. As indicated by adotted line in FIG. 20, when not in contact with the paper roll 100 a,the contact part 60D protrudes from the inner wall of the cover 20A.When the paper roll 100 a moves toward the cover 20A and contacts theangled portion 61D, the angled portion 61D formed of a sponge is pressedand deformed.

The deformed angled portion 61D biases the paper roll 100 a to the rightin FIG. 20. As a result, the moving force of the paper roll 100 a isreduced, and the rubbing sound generated when the paper roll 100 acontacts the angled portion 61D is reduced. Also, because the contactpart 60D is formed of a sponge, the rubbing sound is absorbed by thecontact part 60D, and the quietness of the printer 1D is improved.

The hardness of the sponge forming the contact port 60D and the force atwhich the contact part 60D presses the paper roll 100 a are set atappropriate values so that indentations are not formed on the recordingpaper 100.

FIGS. 21 and 22 illustrate the printer 1E according to a fifthembodiment. FIG. 21 is a plan view of the cover 20A, and FIG. 22 is across-sectional view of the printer 1E with the cover 20A closed.

The printer 1E of the fifth embodiment includes a contact part 60Eincluding multiple angled portions 61E. In the example of FIG. 21, thecontact part 60E includes five angled portions 61E, and each angledportion 61E includes a peak portion 64E that protrudes upward. The endsof each angled portion 61E are attached via attaching portions 62E tothe cover 20A. The height of the peak portion 64E is greater than themaximum radius of the paper roll 100 a placed in the housing chamber 15.

The peak portion 64E of each angled portion 61E may not necessarilyprotrude upward, and may be configured to protrude downward. Also, thecontact part 60E may include angled portions 61E whose peak portions 64Eprotrude upward as well as angled portions 61E whose peak portions 64Eprotrude downward.

As indicated by a dotted line in FIG. 22, when not in contact with thepaper roll 100 a, each angled portion 61E is inclined forward withrespect to the inner wall of the cover 20A. When the paper roll 100 acontacts the angled portions 61E, the angled portions 61E areelastically deformed in a direction D (indicated by an arrow D) towardthe cover 20A.

Accordingly, the moving force of the paper roll 100 a toward the cover20A is reduced as a result of elastic deformation of the angled portions61E. This configuration can reduce the rubbing sound that is generatedwhen the paper roll 100 a contacts the angled portions 61E, and improvethe quietness of the printer 1E.

Also in the fifth embodiment, the angled portions 61E are formed ofwires, and substantially point-contact the paper roll 100 a.Accordingly, the friction between the contact part 60E and the paperroll 100 a is reduced, and the rubbing sound generated when the paperroll 100 a contacts the angled portions 61E is reduced.

Also, because each angled portion 61E has an inverted-V shape, as therecording paper 100 is pulled out and the diameter of the paper roll 100a decreases, the positions on the paper roll 100 a contacting the angledportion 61E change in the width direction of the paper roll 100 a. Thus,the printer 1E can also prevent formation of indentations on therecording paper 100.

Also, because the printer 1E includes multiple angled portions 61E, thepaper roll 100 a point-contacts the angled portions 61E at manypositions. In the printer lE where five angled portions 61E areprovided, the paper roll 100 a and the angled portions 61E contact eachother at ten positions. The configuration where the paper roll 100 a andthe angled portions 61E contact each other at many positions makes itpossible to stabilize the paper roll 100 a even when the recording paper100 is pulled out at high speed, and thereby improve the quietness ofthe printer 1E.

Although the number of contact points between the paper roll 100 a andthe contact part 60E is large, because the paper roll 100 a and theangled portions 61E substantially point-contact each other, the contactarea between the paper roll 100 a and the angled portions 61E is smallerthan the contact area in the case of a surface contact or a line contactin the comparative example. Accordingly, although the paper roll 100 aand the angled portions 61E contact each other at many positions, thefriction between the paper roll 100 a and the angled portions 61E issmall and the rubbing sound does not increase.

FIG. 23 is a plan view of a cover 20B including a detachment preventingmechanism 70B of a sixth embodiment.

The detachment preventing mechanism 70B includes an arched stopper 80B.Grooves 27 formed in the cover 20B are also arranged in an arched linethat corresponds to the shape of the stopper 80B to be fitted into thegrooves 27.

When an external force is applied to the cover 20B and the side plates24 fall inward, an external force F3 is applied to the ends of thestopper 80B. Because the stopper 80B originally has an arched shape, thestopper 80B is deformed in a predetermined direction when the externalforce F3 is applied.

Therefore, even when the external force F3 is applied instantaneously tothe stopper 80B, the stopper 80B deforms in the predetermined directionand is detached from the cover 20B. Forming the stopper 80B in an archedshape makes it possible to prevent the side plates 24 from beingdamaged, prevent the stopper 80B from being broken, and prevent theprotrusions 82 from being crushed. The inner walls of the grooves 27contacting the stopper 80B may be inclined so that the stopper 80B canbe smoothly detached from the cover 20B.

FIGS. 24A and 24B illustrate a cover 20B including a detachmentpreventing mechanism 70C according to a seventh embodiment. FIG. 24A isa plan view of the cover 20B, and FIG. 24B is a side view of the cover20B.

The detachment preventing mechanism 70C includes a stopper 80C with anarched shape, and grooves 27 formed in the cover 20B are arranged inpositions that correspond to the shape of the stopper 80C.

Protrusions 82 formed at the ends of the stopper 80C are rotatablyfitted into the recesses 29 formed in the side plates 24. Thus, thestopper 80C is rotatable relative to the cover 20B.

Also in the seventh embodiment, because the stopper 80C originally hasan arched shape, the stopper 80C is deformed in a predetermineddirection when the external force F3 is applied. Accordingly, when theexternal force F3 is instantaneously applied, the stopper 80C isdetached from the cover 20B. This configuration can prevent the sideplates 24 from being damaged, prevent the stopper 80C from being broken,and prevent the protrusions 82 from being crushed.

To attach the stopper 80C to the cover 20B, the protrusions 82 arefitted into the recesses 29 before placing the stopper 80C into thegrooves 27. In FIGS. 24A and 24B, an arrow PS1 indicates the stopper 80Cthat is not placed in the grooves 27, and an arrow PS2 indicates thestopper 80C that is placed in the grooves 27.

With the protrusions 82 fitted into the recesses 29, the stopper 80C isattached to the cover 20B so as to be rotatable about the protrusions82. Thus, after the stopper 80C is attached to the cover 20B withoutplacing the stopper 80C in the grooves 27 as indicated by the arrow PS1in FIGS. 24A and 24B, the stopper 80C is rotated in a directionindicated by an arrow I in FIG. 24B to place the stopper 80C in thegrooves 27 as indicated by the arrow PS2.

Because the stopper 80C is positioned by coupling the ends of thestopper 80C to the cover 20B, the stopper 80C can be easily placed intothe grooves 27 even though the stopper 80C has an arched shape. Theconfiguration of the detachment preventing mechanism 70C of the seventhembodiment makes it possible to easily attach the arched stopper 80C tothe cover 20B.

The stopper 80C can be detached from the cover 20B by performing theabove process in reverse order. Thus, the stopper 80C can be easilyattached to and detached from the cover 20B.

FIG. 25 is a plan view of a cover 20B including a detachment preventingmechanism 70D according to an eighth embodiment.

A stopper 80D of the detachment preventing mechanism 70D includes astopper body 81D, a shaft 85, and coil springs 86.

The stopper body 81D has a U-shaped cross section, and extends in thewidth direction of the cover 20B. A space is formed inside of thestopper body 81D, and the shaft 85 is passed through the space in thestopper body 81D. The cross-sectional shape of the stopper body 81D isnot limited to a U-shape, and the stopper body 81D may have any othercross-sectional shape such as a circular cross-sectional shape as longas the shaft 85 can be passed through the internal space of the stopperbody 81D.

The length of the shaft 85 is shorter than the distance between the twoside plates 24 indicated by solid lines in FIG. 25. The length of thestopper body 81D is shorter than the length of the shaft 85.

By passing the shaft 85 through the stopper body 81D, the shaft 85 andthe stopper body 81D are fixed to each other, and the ends of the shaft85 protrude from the ends of the stopper body 81D.

The coil springs 86 are attached to the ends of the shaft 85 protrudingfrom the stopper body 81D. The inner ends of the coil springs 86 arefixed to the ends of the stopper body 81D by, for example, welding.

When the stopper 80D is attached to the cover 20B, the stopper body 81Dis fitted into the grooves 27 formed in the cover 20B. Also, when thestopper 80D is attached to the cover 20B, the outer ends of the coilsprings 86 contact the inner walls of the side plates 24.

In the eighth embodiment, when the side plates 24 fall inward and theexternal force F3 is applied inward to the ends of the stopper 80D, thecoil springs 86 contacting the side plates 24 are compressed. In FIG.25, the side plates 24 falling inward are indicated by dotted lines.

In the eighth embodiment, the coil springs are compressed when theexternal force F3 is applied to prevent damage to the side plates 24 andthe stopper 80D.

Embodiments of the present invention are described above. However, thepresent invention is not limited to the specifically disclosedembodiments, and variations and modifications may be made withoutdeparting from the scope of the present invention.

The present application is based on and claims the benefit of priorityof Japanese Patent Application No. 2015-058725 filed on Mar. 20, 2015,the entire contents of which are hereby incorporated herein byreference.

EXPLANATION OF REFERENCE NUMERALS

-   1A-1E Printer-   11 Holder-   12 Circuit board-   15 Housing chamber-   17 Shaft hole-   20A, 20B Cover-   23 Cover body-   24 Side plate-   25 Rib-   26 Protrusion-   27 Groove-   28 Shaft-   29 Recess-   50 Bearing-   60A-60E Contact part-   61A-61E Angled portion-   62A-62E Attaching portion-   64A-64E Peak portion-   65 Edge-   70A-70D Detachment preventing mechanism-   80A-80D Stopper-   82 Protrusion-   83 Stopper surface-   85 Shaft-   86 Coil spring-   100 Recording paper-   100 a Paper roll

1. A printer, comprising: a holder configured to house rolled recordingpaper; a cover that is attached to the holder to be openable andclosable relative to the holder; and a contact part that is attached tothe cover and configured to contact the recording paper, wherein thecontact part is configured such that the contact part substantiallypoint-contacts the recording paper, and positions on the contact partcontacting the recording paper change as the recording paper isunrolled.
 2. The printer as claimed in claim 1, wherein the contact partincludes a wire.
 3. The printer as claimed in claim 1, wherein thecontact part is formed of a metal plate.
 4. A printer, comprising: aprinter body including a holder; a cover configured to open and closethe holder, the cover and the holder forming a housing chamber forhousing rolled recording paper; and a sound-absorbing material includingone or more angled portions and disposed in the housing chamber suchthat the recording paper contacts the sound-absorbing material as therecording paper is unrolled, wherein the sound-absorbing material isconfigured to substantially point-contact the recording paper.